This document compares the effects of olive oil, coconut oil, and butter on adipose tissue, liver tissue, and serum lipid profiles in albino rats. It finds that coconut oil has the highest saturated fat content. Females were more affected than males in their lipid profiles and relative liver and heart weights. Microscopic examination found histopathological changes in livers of rats fed different fats. The conclusion is that saturated fatty acids generally raise cholesterol levels, while monounsaturated fatty acids are neutral or mildly lowering and polyunsaturated fatty acids are cholesterol-lowering.

1. IOSR Journal of Biotechnology and Biochemistry (IOSR-JBB)
e-ISSN: XXXX-XXXX, p-ISSN: XXXX-XXXX, Volume 1, Issue 3 (Mar. – Apr. 2015), PP 28-38
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Compare Effect of Fatty Acid Composition (Olive, Coconut Oil
and Butter) on Adipose Liver Tissue, and Serum Lipid Profile in
Albino rats
Hanaa H Elsayed1
, Mohammed K. Abd Elrahman1
, Amal H Emara1
and
AmrAbd El-Hafez2
1Chemistry of Nutrition and metabolism Department, National Nutrition Institute (NNI) –Cairo, Egypt.
2Hotel Department Higher Institute for Tourism & Hotel in 6th
October City
Abstract:Different classes of fatty acids appear to have different effects on body fat increase. Consequently, a
need exists to evaluate the effects of various fatty acid classes on body composition and body fat distribution.
Based on the above rationale, a study was designed to evaluate the biological effects of conventional olive oil,
coconut oil and butter for comparisoneffects of fatty acids content of oils and butter on adipose liver tissue and
serum lipid profile. For this purpose, forty rats, (20male and 20 female) fed on standard diet for one week as
adaptation,after that scarified 10 rats as baseline group and distributed 30 rats to three groups (each 5 rat male
and 5 female). Group (A) fed standard diet contain 10% olive oil, group (B) fed standard diet contain 10%
coconut oil and group (C) fed standard diet contain 10% butter fat for four weeks.Results showed that coconut
oil was the highest of saturated fatty acid. Femalesweremore affected thanmales in lipid profile and relative
weight of liver and heart. In addition the microscopically examination for liver of rats fed different fat
includedbaselinegroup showedhistopathological alteration. Conclusion, serum cholesterol concentration,
saturated fatty acid (SFA) is generally considered to be hypercholesterolemic, whereas monounsaturated fatty
acids are thought to be neutral or mildly hypocholesterolemic, while poly unsaturated fatty acid (PUFA) are
hypocholesterolemic. Categorizing dietary fatty acids according to degree of saturation has been useful in
developing dietary recommendations, although individual fatty acids within the same saturation category can
have very different and specific effects on cholesterol metabolism.
Key words:Fatty acid, coconut oil, olive oil, butter fat, rats, lipid profile
I. Introduction:
Nutrients regulate cellular functions at multiple levels through modulation of transcription, translation
and activity of various enzymes. Fatty acids, especially polyunsaturated fatty acids (PUFA), modulate
abundance and activity of key transcription factors such as sterol regulatory element binding proteins and
peroxisome proliferator-activated receptors g (PPARg) to regulate adipose tissue function (Al-Hasani and
Joost 2005).
Recently, research shows that the total amount of fat in the diet isn’t really linked with weight or
disease. While that really matters is the type of fat and the total calories in the diet [(Menteet al., 2009 and
Mozaffarian, et al., 2011)]. RH & SS, (1991) who was suggested an appreciable reduction in saturated fatty
acids (SFA) from present levels of intake in most western countries to reducing coronary heart disease (CHD).
A major justification for this recommendation is the association between SFA and total and low density
lipoprotein (LDL) cholesterol. Despite the clear demonstration that stearic acid (C18: O) has a negligible effect
on total and LDL cholesterol (Bonanome and Grundy, 1988), therecommendations have not attempted to
distinguish between individual SFA. In view of potentially undesirable effects of high intakes of n-6
polyunsaturated fatty acids (PUFA) (Sheherd, et al., 1978; Mattson, and. Grundy. 1985 and Jackson, et al.,
1984), which are commonly used to replace SFA, it seems important to establish more precisely the effects of
individual SFA on lipids and lipoproteins and also to compare the effects of widely used for fats with varying
proportions of saturated fatty acids. The early studies and apparently contradictory results of Keys, et al., (1965)
and Hegstedet al., (1965) regarding the hypercholesterolemic effect of various saturated fatty
acids.WhileDenke, & Grundy,(1992), and Zock, et al.,(1994) who studied that the cholesterol-raising from
three saturated fatty acids, whichappear the effect of myristic acid is most marked then palmitic acid greater
than lauric acid.
Butter has appreciable amounts of butyric acid, used by the colon as an energy source. This fatty acid is
also a known anti-carcinogen. Lauric acid, a medium chain fatty acid, is a potent antimicrobial and antifungal
substance. Butter also contains conjugated linoleic acid (CLA) which gives excellent protection against
cancer.Butter is rich in trace minerals, especially selenium, a powerful antioxidant. Ounce for ounce, butter has
more selenium per gram than either whole wheat or garlic. Butter also supplies iodine, needed by the thyroid

2. Compare Effect of Fatty Acid Composition (Olive, Coconut Oil and Butter) on Adipose Liver ….
www.iosrjournals.org 29 | Page
gland (as well as vitamin A, also needed by the thyroid gland).Butter is a rich source of easily absorbed vitamin
A, needed for a wide range of functions in the body, from maintaining good vision, to keeping the endocrine
system in top shape. Butter also contains all the other fat-soluble vitamins (E, K, and D) (Byrnes, 2001).
Coconut oil has >90% saturated fatty acids, hence is less attractive to consumers. Also, it is rich in
short and medium chain fatty acids (MCTs). Shorter chain length allows fatty acids to be metabolized without
use of the carnitine transport system (Gopala -Krishna, et al., 2010).MCTs have a different pattern of
absorption and utilization than long chain triglycerides (LCTs) that make up 97 percent of dietary fats. MCTs
are transported into the mitachondria independent of the carnitine shuttle, which is necessary for LCT
mitochondrial absorption. Oxidation of MCTs provides 8.3 calories per gram, while LCTs provides 9.2 calories
per gram. They go straight to the liver from the digestive tract, where they are used as quick source energy or
turned into so-called ketone bodies, which can have therapeutic effects on brain disorders like epilepsy and
Alzheimer’s (Heydnger and Nakhasi, (1996).
Olive oil, the main fatty component is characterized by consisting of monounsaturated fatty acids as
well as by its elevated content in antioxidant agents. This oil exhibits numerous biological functions which are
beneficial for the state of health. Olive oil is able to scavenge free radicals and afford an adequate protection
against peroxidation. On the other hand, several investigations have suggested that olive oil can be beneficial in
inflammatory and autoimmune diseases, such as rheumatoid arthritis. Finally, it has been demonstrated that a
diet rich in olive oil is associated with a high percentage of gastric ulcer healing and affords a higher resistance
against non-steroidal anti-inflammatory drugs-induced gastric ulcer genesis (La Lastra, et al., 2001).
The experiment was designed to compare the effects of the types and sources of dietary fats on adipose
liver tissueand lipid profile in rats.
II. Material and Methods:
Materials:
Chemicals: DL-methionine, choline chloride, vitamins, and minerals, required were obtained from El-
Gomhorya Company for chemicals and Drugs, Cairo, Egypt.
Skimmed milk, corn starch, Olive oil, coconut oil and butter required for preparing experimental diets
were purchased from local market, Cairo, Egypt.
Experimental animals:forty healthy adult male and female albino rats "Sprague Dawley strain" weighing (100
± 10g.) were obtained from vaccine and immunity organization Helwan Farm, Cairo, Egypt.
Kits for biochemical analysis were obtained from El-Gomhorya Company for chemicals and drugs, Cairo,
Egypt.
Diets, standard diet was prepared from fine ingredients per 100g. The diet had the following composition:
sunflower oil 10%; salt mixture 4% according to Hegestedet al, (1941), vitamin mixture 1% according to
Campbell (1961), choline chloride 0.2%, DL-methionine 0.3% and protein was added 12% from skimmed milk
according to Reeves et al., (1993).
Experimental design:
Forty healthy adult albino rats "Sprague Dawley strain" weighing (100± 10g.) Food and water were
administrated ad-libitum during the period of experiment (4 weeks) and was approved by the experiments
animal unit- National Nutrition Institute.
Figure 1 Experimental design

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At the end of experiment, the animals were fasted overnight, and then sacrificed after anesthesia and
blood samples were taken from hepatic portal vein. The rest of the blood were left in centrifuge tube at room
temperature for 15 min. sample and then centrifuged at 4000 r.p.m. for 15 minutes. Serum was separated in
plastic tube at -20o
C until analysis. Heart, liver, and kidney removed, washed in saline (NaCl) solution 0.9%,
and dried with filter paper then weighed. Part of liver was fixed in formalin solution 10% then subjected to
histological examination. Other part of liver storage at-20o
C until analysis.
Biological Parameters:
 Body weight gain (BWG): Animals were weighed twice a week. At the end of experiment calculated for
them as a mean and standard error for each group.
Body weight gain= final body weight – initial body weight
 Feed efficiency ratio (FER): Calculated according to Eggum et al., (1973) as follows:
Feed efficiency ratio = Body weight / Feed intake
 Relative weight organs (RWO): Calculated as follows:
Relative organs = Organ weight / Final body weight X100
Chemical analysis:
Gas Chromatography Mass Spectrometry (GC Mass) was used to analyze the fatty acid content of olive
oil, coconut oil and butter fat according to (AOAC 2001).
Biochemical analysis
In liver tissue determined, T. lipid, triglyceride (TG) according to Bligh, and Dyer (1959) and
Malondialdehyde (MDA) measured colourimetrically according to the method of Uchiyama &Mihara (1978).
In serum, total triglycerides (TG) and high-density lipoprotein (HDL) were measured using commercially
available kits according toWahlefeld, (1974) and Stein, (1986).Serum total cholesterol (TC) was estimated
using a spectrophotometer Stein, (1986). Low-density lipoprotein (LDL) was calculated from TC, HDL and TG
values by an equation according to Friedewaldet al., (1972): LDL =TC _ HDL _TG/5
Statistical analysis:
Statistical analysis of the results by using computer program (SPSS), Independent F-test and one-way
analysis of variance (ANOVA) were used, the difference was considered significant at P-value < 0.05 (Zar,
1984)
III. Results and discussion
Dietary fats are found in both plant and animal foods. Fats supply the bodywith calories and essential
fatty acids, and help in the absorption of the fat-soluble vitamins A, D, E, and K.The fatty acid percent
composition of tested oils and butter fat were as a relative percentage.
Table (1) Fatty acid profile for olive oil, coconut oil and butter
Saturation Fatty acid Olive oil Coconut oil Butter fat
Saturated fatty acid Butyric acid --- --- 2.27
Valeric acid --- --- 0.02
Capric acid --- 0.53 1.54
Caprylic acid ---- 7.78 0.91
Caproic acid ---- 7.19 1.97
Nonanoic acid --- 0.01 0.01
Undecanoic acid --- 0.03 --
Lauric acid 0.02 35.25 2.66
Tridecanoic acid 0.03 0.07
Myristic acid 0.04 19.17 13.65
Pentadecanoic acid --- 0.02 2.29
Palmitic acid 18.21 12.6 34.26
Margaric acid 0.03 0.01 1.42
Stearic acid 0.20 3.99 18.36
Arachidic acid 0.22 0.09 0.23
Heneicosanoic acid ---- --- 0.11
Behenic acid 0.04 0.03 0.13
Tricosanoic acid --- 0.01 0.08
Lignoceric acid 0.04 0.03 0.09
Mono-unsaturated fatty
acid
4 Decenoic acid --- --- ---
PalmitOleic acid 1.33 0.06 1.08

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Oleic acid 66.70 10.54 16.42
10 Nonadecenoic acid -- -- 0.23
11-Eicosenoic acid 0.11 0.06 0.08
poly-unsaturated fatty
acid
Linoleic acid 12.59 2.58 1.79
Linolenic acid 0.47 0.01 0.07
Linoelaidic acid --- -- --
Arachidonic acid --- -- --
Total saturated fatty acid 18.80 86.75 80.33
Total unsaturated fatty acid 81.20 13.25 19.67
The result of analysis showed that the percentage of the total SFA ranged from 18.8% for olive oil to
86.75 and 80.33% for coconut oil and butter fat respectively, with the predominant presence of palmetic acid
(C16:0) for olive oil; with the predominant presence of lauric acid (C12:0) followed by Myristic acid (C14:0)
and palmetic acid (C16:0) for coconut oil; and with the predominant presence of palmitic acid(C16:0) followed
by stearic acid (C18:0) and myrestic acid (C14:0).
Table (1) clarified butter differentiated by the presence of Butyric acid, and increase in caproic acid,
palmitic acid and Stearic acid than other fat. Lauric acid found in coconut oil (35.25% from total fatty acid)
follows myristic acid (19.17 %) then caprylic acid and capric acid. The total content of unsaturated fatty acid
(USFA) was the highest in olive oil (81.2%) and the lowest content was (13.25 %) for coconut oil but the
moderate in butter fat. Olive oil Marked by Oleic acid follows linoleic acid.
Regarding to table (1) showed that the results disagreed with Gunstone, (1986) who estimated fatty
acids in each of butter, coconut oil and olive oil, who showedthat increase in butyric acid, capric acid, caproic
acid and lauric acid in butter than the present results in table (1),whilemyristic acid, palmitic acid and stearic
acid had decreased. Also, he showed higher in Mono-unsaturated fatty acid and poly-unsaturated fatty acid than
finding in the present investigation. Gunstone, (1986) explained that coconut oil had 90% saturated fatty acids
compared with data in table (1) which was 86.75. In additionhe foundthat olive oil had increased in unsaturated
fatty acid compare to data in table (1). Data in the same table was confirms a previous study by Nakbiet al.,
(2010) who evaluated fatty acid profile of olive oil (SFA 17.28 ± 0.22, MUFA 66.20 ± 2.34 and PUFA 14.99 ±
0.94).
Butyric acid (originally isolate in butter) is known to have varying degrees of antimicrobial activity.
This fatty acid is absorbed directly into the colon and serves as energy in that way. Butyric acid has been shown
to have anti-tumor properties. Butyric acid is used to treat cancer (Lim Sylianco, 1987).
Mensink, &Katan (1990) said that the major sourcesof palmitic acid are butter fat, and two vegetable
oils, coconut oil and palm kernel oil; the latter two also contain large amounts of lauric acid. While the palm oil,
(another vegetable oil) is high content saturated fatty acids, is low in myristic acid and high in palmitic
acid.Myristic acid has been reported to be the strongest serum cholesterol elevating fatty acid (Hegstedet al.,
1965). Mensink, et al, (2003) reported that Lauric acid is effective in treating viral infections and raises HDL.
Meta-analyses of dietary trials that employed commercially available fats indicate that myristic acid
might be four to six times more cholesterolemic than palmitic acid (Mensink and Katan, 1992). Some recent
studies also suggest that palmitic acid lowers cholesterol relative to a mixture of lauric acid and myristic acid
(Sundramet al., 1991 and Ng TKW, et al., 1992). However, others have found that palmitic acid strongly
increases cholesterol levels [Bonanome& Grundy (1988); Denke, & Grundy (1992) and Nestelet al.,
(1992)].
Initially, stearic acid, a saturated fatty acid, was considered to have no effect on serum cholesterol
(Keys et al., 1965 and Grande et al., 1970), butBonanomeet al., (1992)reported it has been lower serum
cholesterol. Kris-Ethertonet al., (1993) showed that stearic acid has unique effects on plasma total cholesterol
levels compared with other long-chain saturated fatty acids. Author also has shown that linoleic acid has a more
potent hypocholesterolemic effect than oleic acid and does not affect HDL cholesterol levels or HDL
composition.
Monounsaturated fatty acid effects were first considered as being neutral with regard to serum
cholesterol (Keys, et al., 1957); however the work of Grundy, (1989) has shown that monounsaturated fatty
acids are as effective as polyunsaturated fatty acids in lowering serum cholesterol.
The early classical studies (Ahrens, et al., 1957 and Keys, et al, 1957) indicated diets containing high
levels of polyunsaturated fatty acids were effective in lowering serum cholesterol levels; however studies in
recent years have demonstrated that dietary polyunsaturated fatty acids also lower.
Olive oil is far higher in monounsaturated fatty acids than any other fat or oil. Unsaturated fatty acids
are thought to be better for health than saturated fatty acids, with monounsaturated ones being the best (Boyle &
Anderson 2007).

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Table (2) Relative weight of some organs, weight Change and feed efficiency during experimental feeding on
different fat diets (mean ± SE)
Sample
Parameter
Sex Baseline group
Olive oil
group
Coconut
oil group
Butter group P value
Relative weight of
Liver
Male 2.8 ± 0.46 3.2 ± 0.37 3.9 ± 0.48 3.4 ± 0.3 0.381
Female 2.97 ± 0.14 4.1 ± 0.39 3.92 ± 0.13 4.05 ±0.09 0.023*
P value 0.351 0.056 0.451 0.049* ---
Relative weight of
Kidney
Male 0.6 ±0.05 0.86 ±0.1 0.8 ±0.07 0.72 ±0.05 0.254
Female 0.67±0.09 0.86±0.07 0.75±0.06 0.8±0.03 0.242
P value 0.281 0.5 0.309 0.131 --
Relative weight of
Heart
Male 0.5±0.1 0.26±0.02 0.38±0.03 0.3±0.01 0.008*
Female 0.43±0.03 0.34±0.02 0.3±0.04 0.34±0.04 0.173
P value 0.281 0.024* 0.096 0.173 --
BWG
Male 30.4±7.6 25.2±3.3 34.4±5.3 0.535
Female 28.5±4.9 29.5±4.6 39.0±1.0 0.176
P value 0.42 0.24 0.22 ---
FER
Male 8.42±0.96 8.98±0.54 9.2±0.99 0.806
Female 7.6±0.5 8.55±0.4 9.5±0.3 0.023*
P value 0.242 0.266 0.382 --
*Significant is P< 0.05
Table (2) clarified that relative liver weight of all female groups fed on different fat diets higher than in
male groups. This increase wasno significant differences compare all groupexcept rat fed on butter fat had
significantly between male and female. While within female groups fed all type fat showed significantly
differences. Coconut oil as a source fat had the highest relative weight of liver in female groups but it was the
lowest in male. Olive oil was contrary to theresult of coconut oil. The weight of liver increased significantly
may be due to accumulation of fat in the cells of the liver due to high level of cholesterol and other fats in the
blood, its uptake by HDL and return to the liver to metabolism and excretion with urine and fecal. The results go
in the same line with that reported by Jennings et al., (1988) who observed that 1% cholesterol feeding
increased total liver lipids almost three folds and liver cholesterol concentration almost 10-folds which
significantly increase in liver weight. In a study by Ahmad et al.,(2007) the weight of liver was significantly
higher in rats given 7% fish oil and soybean oil for 7 weeks. Similarly Astorg and Levillain(1979) found that
erucic acid induce an increase in liver weight. Imofidon and Okunrobo(2012) showed that the increase in liver
weights of rats that received a 10% palm and groundnut oil supplemented diet was accompanied with a mild
inflammation in the liver. Kritchevskyet al.,(1983) detected that rats were fed on 14% cocoa butter for 21 days
had a lower relative liver weight compared to those rats that received the same percent of corn, and palm kernel
oil.
Regarding to data in table (2) found that increased in relative weight of kidney in all groups fed on diet
containing olive and coconut oil and better compare to baseline group while no significant differenceswithin this
groups or between male and female. Results in present study in accordance with study byMorisseyet al.,
(1986)showed that there were no pathological abnormalities due to the addition of cocoa butter up to 30% for 90
days. This may explain the reason why there is no difference in terms of the kidney weights in this study. Olive
oil showed nearest results of relative kidney weightfor male and female rats. Butter observed higher relative
kidney weight in female than male rats while coconut oil showed converse with butter results.
Results of relative heart weight showed a significant difference for male groups but female no
significantly. Olive oil groupexplaineda significant difference between female and male groups. These results in
agreement with Alaamet al., (2012) who observed no significant differences in hearts relative weights among
all the tested rat groups and control rats.
Findings of this study noticed that gradual increase in body weight of all the animals with advancing
the experimental period. It was cleared that the growth performance of rats was not significantly (p<0.05)
affected by the dietary (olive, coconut oil and butter fat) and weight change; there were no significant difference
between groups male or female.These results agreed with findings obtained by Alaamet al.,(2012) who studied
compare palm oil, palm olein, palm steatin and corn oil and Yamasaki et al., (2001) who found that rats weight
gain no significant difference between groups fed different oils (olive, sesame or peanut) as a source fat in diet.
The phenomenon in table (2)appeared that feed efficiency ratio of female groups fed different type
offat had significant differences, while there were no significant differences between all male groups or between
male and female groups. Olive oil showed the lowest FER for male and female but butter fat was the highest.
These results agreed withEbru, et al., (2014) who found the cocoa butter was higher in total feed composition
than sunflower oil or blend from cocoa butter and sunflower oil.

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Table (3) Changes in serum lipid profile [mg/dl] of rats during experimental feeding on different fat diets (mean
± SE)
Groups
parameters
sex
Baseline
group
Olive oil
group
Coconut
oil group
Butter group P value
T. lipid
male
613.0
±28.7
947.6
±91
1166.4
±154.8
1013.8
±53.4 0.033*
%of
Baseline
-- 155 190 165
female
638.3
±29.2
723.0
±68.5
1008.8
±99.6
858.5
±49.7 0.020*
%of
Baseline
-- 113 158 134
P value -- 0.285 0.045* 0.210 0.035* --
Triglyceride
male
91.3
±7.3
78.3
±7.4
121.2
±16.3
112.8 ±12.5
0.090
%of
Baseline
-- 86 133 124
female
83.3
±2.3
71.5
±8.6
122.3
±8.3
103.8
±12.2 0.010*
%of
Baseline
-- 86 147 125
P value -- 0.177 0.283 0.478 0.311 --
T. cholesterol
male
107.3
±3.8
103.6
±1.5
164.6
±10.8
150.2
±14.3
0.001*
%of
Baseline
-- 97 153 140
female
102.7
±6.6
123.3
±20.2
206.8
±5.3
168.8
±5.9
0.0003*
%of
Baseline
-- 120 201 164
P value -- 0.286 0.202 0.006* 0.143 ---
HDL
male
36.2
±4.7
38.9
±7.6
56.2
±8.3
54.6
±7.0
0.199
%of
Baseline
-- 107 155 151
female
41.6±
0.9
35.7±
4.3
55.2±
3.9
50.8±
7.4
0.089
%of
Baseline
-- 86 133 122
P value -- 0.158 0.363 0.458 0.359 --
LDL
male
55.1
±8.3
70.5
±12.9
85.8
±14.2
96.4
±20.0
0.369
%of
Baseline
-- 128 156 175
female
44.5
±6.1
72.8
±18.7
104.8
±7.0
96.3
±8.1
0.010*
%of
Baseline
--- 164 236 216
P value -- 0.180 0.461 0.058 0.497 --
*Significant is P< 0.05
Results in table (3) showed that rats (male and female) groups that were fed on coconut oil had the
highest percent of serum total lipid. There were significant differences in serum total lipid between groups fed
on olive, coconut oil and butter fat compare with baseline group. In addition there were no significant
differences in between two six of rat that were fed coconut oil diet, while result showed a significant differences
in between male and female rats that were fed butter fat and olive oil diets.
Data in table (3) observed that serum triglyceride level in both male and female rats that were fed on
coconut oil diet were highly percentage followed by butter fat diet then olive oil diet. Data also illustrated that
all female rats that were fed different fat diet were had a significant differences in serum triglyceride comparing
to results ofbaseline group. In contrast, all male rats that received on olive oil butter fat and coconut oil dietshad
no significant differences in serum triglyceride. Also, there were no significant differences between male and
female rats fed on all fatdiets.
In table (3) male and female rats that were fed on coconut oil diet were higher in serum total
cholesterol than groups fed on other source of fat but it differences were significant in related to baselinegroup.

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Total cholesterol levels were higher in female rats that were fed on different source of fat than male rats, but
there were no significant difference betweenthem fed all source of fat except in coconut oil diet group.
HDL and LDL-cholesterol levels were the highest in rats fed on diet with coconut oil andthe lowest in
groups fed on diet olive oil, with intermediate levels in rats fed on diet butter fat; all differences among the
feeding periods were statistically significant (P < 0.05) this trends were apparent in female groups.
Results in this study confirmed by Mensink, et al, (2003) who explained that coconut oil contains a
large proportion of lauric acid, a saturated fat that raises total blood cholesterol levels by increasing both the
amount of high-density lipoprotein (HDL) cholesterol and low-density lipoprotein (LDL) cholesterol. Although
this may create a more favorable total blood cholesterol profile, this does not exclude the possibility that
persistent consumption of coconut oil may increase the risk of cardiovascular disease through other
mechanisms(Mensink, et al, 2003), Because much of the saturated fat of coconut oil is in the form of lauric acid
(which raises HDL).
A major proportion of saturated fats of coconut oil are formed of medium chain fatty acids, which do
not require a re- esterification process and are oxidized immediately for energy need in the liver (Guillot, et al.,
1993). Due to this specific characteristic of medium chain fatty acids, it has also been reported that coconut oil
cannot be considered hypercholesterolemic(Reiser, 1973).
Stearic acid in butter fat is higherlevel than coconut oil that is less absorbed than other fatty acids.
Thus, the bioavailability of butter is low (Weisburger, 2001). Group rats fed on butter diet showedtheir total
cholesterol and triglyceride level lower than group rats fed on coconut oil. In study conducted on rats, cocoa
butter diet has been shown to lower cholesterol and triglyceride levels (Kiitchevsky, et al., 1988).The saturated
fatty acids, except perhaps stearic acid (Packard et al., 2000),increase circulating VLDLs, LDLs, cholesterol,
and triglycerides (TGs).In addition, saturated fatty acids including stearic acid may predispose platelets to
aggregation and facilitate thrombosis (Kushwaha, &Hazzard, 1977).
Olive oil has decreases the plasmatic levels of LDL-cholesterol and increases those of HDL-
cholesterol, hence diminishing the risk of suffering from heart complaints. In this context, it has been suggested
that increased consumption of monounsaturated fatty acids in place of polyunsaturated fatty acids will render
circulating lipoproteins less sensitive to peroxidation and thereby diminish the development of
atherosclerosis(La Lastra, et al., 2001).
Table (4) Lipid profile in liver tissue of rat that fed on diets with different source of fat (mean ± SE)
Groups
parameters
Sex
Baseline
group
Olive oil
group
Coconut oil
group
Butter group P
value
MDA
µmol/g liver tissue
Male
55.3
±1.1
59.8
±8.2
65.5
±12.3
52.3
±5.2 0.7228
%of
Baseline
-- 108 118 95
Female
55.6
±4.5
61.2
±5.8
59.8
±16.6
50.8
±1.4 0.8607
%of
Baseline
- 110 108 91
P value 0.474 0.458 0.196 0.391 --
T. lipid
mg/ g liver tissue
Male
2328.8
±237.5
2966.6
±402. 4
3110.2
±436.6
1901.3
±342.7 0.142
%of
Baseline
-- 127 134 82
Female
3239.5
±676.5
1786.5
±235.8
2077.9
±202.6
2819.0
±510.7 0.167
%of
Baseline
-- 55 64 87
P value 0.136 0.032* 0.049* 0.105 --
Triglyceride
mg/ g liver tissue
Male
476.7
±190.2
369.4
±132.0
402.4
±127.1
417.1
±91.9 0.956
%of
Baseline
-- 77 84 87
Female
358.2
±67.7
243.5
±32.0
345.1
±43.1
491.9
± 49.9 0.177
%of
Baseline
-- 68 96 137
P value 0.295 0.203 0.346 0.362 ---
Significant is P< 0.05
In table (4) found that malonaldehyied (MDA)value that indicated to oxidation in tissue lipid had no
significant differences between all groups of rats that were fed on different source of fat or between male and

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female in each group. Although group fed on coconut oil in both six were the highest percent in MDA while
group fed butter had lower in MDA level than two oil and baseline groups.
In the same table clarified that total lipid in tissue for all groups of rats that were fed on different source
of fat had no significant differences compare baseline group, while there were significant differences between
female and male groups fed olive and coconut oil. Male groups fed coconut oil and olive oil had increased
percent in total lipid compare female groups, while female group fed butter had the highest percent in total lipid.
In addition tissue triglyceride value showed that there were no significant differences between all
groups fed on different source fat or compare male and female groups. Male and female groups fed on butter fat
were the highest percent followed coconut oil then olive oil groups.
This finding was accordance with Ding et al. (2003) who observed that the variations from the fatty
acid composition of diet in adipose tissue can also arise due to preferential exclusion or incorporation of a
particular type of fatty acid into complex lipids. The liver participates in uptake, oxidation and metabolic
conversion of free fatty acids, synthesis of cholesterol, phospholipids and triglycerides (Akhtarand Ali, 1984).
Lipid structure, composition and configuration in addition to excessive fat and cholesterol consumption affect
the lipid profile in plasma (Kritchevsky, 1995), as well as fat tissue deposition (Yaqoob, et al., 1995)
Photo (1): Liver of group (Baseline) (I) showing fatty change of
hepatocytes and small focal hepatic necrosis associated with inflammatory
cells infiltration (H & E X 400).
Photo (2): Liver of group (Baseline) (II) showing steatosis of
hepatocytes(H & E X 400).
Photo (3): Liver of group (olive oil) (1) showing congestion of central vein
and slight activation of Kupffer cells (H & E X 400).
Photo (4): Liver of group (olive oil) (1) showing fatty change of
hepatocytes(H & E X 400).
Photo (5): Liver of rat from group (coconut oil) (1) showing fatty change
of hepatocytes and sinusoidal leukocytosis (H & E X 400).
Photo (6): Liver of rat from group (coconut oil) (11) showing steatosis
of hepatocytes(H & E X 400).
Photo (7): Liver of rat from group (butter fat) showing steatosis of
hepatocytes and apoptosis (H & E X 400).
Photo (8): Liver of rat from group (butter fat) showing fatty change of
hepatocytes, apoptosis of hepatocytes and sinusoidal leukocytosis (H &
E X 400).

9. Compare Effect of Fatty Acid Composition (Olive, Coconut Oil and Butter) on Adipose Liver ….
www.iosrjournals.org 36 | Page
Al-Rawi and Ali (2010),feeding on 10% of diet olive oil rat liver of group revealing loss of the normal
radiating pattern with cells slowly turning into large "foam cells" so-described because of their changed
appearance resulting from the numerous internal cytoplasmic vesicles .The cells contained high lipid content
and pyknotic nuclei with loss of their polyhedral shape. Foam cells eventually die, and further propagate the
inflammatory process.
Alaam et al., (2012)showed feeding on palm olein dietary oil as a source saturated fatty acid caused a
dilatation and congestion of the central vein also, a dilatation and congestion of the portal vein with distention
bile duct was noticed, while a normal structure of the surrounding hepatocytes were observed in rats liver.
Concerning the liver of rats group fed on palm oil, showed a few fatty changes in hepatocytes with
inflammatory cells infiltration in between the hepatocytes; in addition of fibrosis with inflammatory cells
infiltration in the portal area.
Alwan, (2009) reported histological examination of liver tissues section of hypercholesterolemic
rabbits revealed hyperatrophic hepatocytes, hardly apparent sinusoids with fatty infiltration these may be due to
increase the level of cholesterol and other lipids in the blood and therefore the liver uptake these increase in
levels to oxidation and metabolism to decrease these levels and increase excreted with urine and feces.
IV. Conclusion
Dietary fatty acids influence several aspects of cholesterol metabolism including cholesterol
absorption, bile acid synthesis, biliary cholesterol secretion, hepatic VLDL synthesis, and LDL clearance from
the circulation. With respect to plasma cholesterol concentration, SFA are generally considered to be
hypercholesterolemic compared with dietary carbohydrate, whereas monounsaturated fatty acids are thought to
be neutral or mildly hypocholesterolemic, and PUFA are hypocholesterolemic. Categorizing dietary fatty acids
according to degree of saturation has been useful in developing dietary recommendations, although individual
fatty acids within the same saturation category can have very different and specific effects on cholesterol
metabolism.
The findings suggest that, in certain circumstances, coconut oil might be a useful alternative to butter
and hydrogenated vegetable fats. However, it should be noted that in individuals and populations with a
tendency to obesity, all fat sources should be restricted and that depending upon the requirements of individuals,
fats high in stearic acid or cis-monounsaturated fatty acids may be preferable to coconut oil.
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